3D Geometry for Computer Graphics

3D Geometry forComputer Graphics Class 2

The plan today • Basic linear algebra review • Eigenvalues and eigenvectors • Why?? • Manipulations of 3D objects require (linear) transformations • Need to understand and analyze linear stuff

Motivation – Shape Matching There are tagged feature points in both sets that are matched by the user What is the best transformation that aligns the unicorn with the lion?

Motivation – Shape Matching Regard the shapes as sets of points and try to “match” these sets using a linear transformation The above is not a good alignment….

Motivation – Shape Matching Regard the shapes as sets of points and try to “match” these sets using a linear transformation To find the best rotation we need to know SVD…

Principal Component Analysis y x Given a set of points, find the best line that approximates it

Principal Component Analysis y’ y x’ x Given a set of points, find the best line that approximates it

Principal Component Analysis y’ y x’ x When we learn PCA (Principal Component Analysis), we’ll know how to find these axes that minimize the sum of distances2

PCA and SVD • PCA and SVD are important tools not only in graphics but also in statistics, computer vision and more. • To learn about them, we first need to get familiar with eigenvalue decomposition. • So, today we’ll start with linear algebra basics reminder. SVD: A = UV T is diagonalcontains the singular values of A

Vector space • Informal definition: • V  (a non-empty set of vectors) • v, w V  v + w  V(closed under addition) • vV,  is scalarv V (closed under multiplication by scalar) • Formal definition includes axioms about associativity and distributivity of the + and  operators. • 0 V always!

Subspace - example • Let l be a 2D line though the origin • L = {p – O | p l} is a linear subspace of R2 y x O

Subspace - example • Let  be a plane through the origin in 3D • V = {p – O | p } is a linear subspace of R3 z y O x

Linear independence • The vectors {v1, v2, …, vk} are a linearly independent set if: 1v1 + 2v2 + … + kvk = 0  i = 0  i • It means that none of the vectors can be obtained as a linear combination of the others.

Linear independence - example • Parallel vectors are always dependent: • Orthogonal vectors are always independent. v = 2.4 w v + (2.4)w = 0 v w

Basis of V • {v1, v2, …, vn} are linearly independent • {v1, v2, …, vn}span the whole vector space V: V = {1v1 + 2v2 + … + nvn | iis scalar} • Any vector in V is a unique linear combination of the basis. • The number of basis vectors is called the dimension of V.

Basis - example • The standard basis of R3 – three unit orthogonal vectors x, y, z: (sometimes called i, j, k or e1, e2, e3) z y x

Basis – another example N M • Grayscale NM images: • Each pixel has value between 0 (black) and 1 (white) • The image can be interpreted as a vector  RNM

The “standard” basis (44)

Linear combinations of the basis *1 + *(2/3) + *(1/3) =

There are also other bases! • The cosine basis – used for JPEG encoding

Matrix representation • Let {v1, v2, …, vn} be a basis of V • Every vV has a unique representation v =1v1 + 2v2 + … + nvn • Denote v by the column-vector: • The basis vectors are therefore denoted:

Linear operators • A : V  W is called linear operator if: • A(v + w) = A(v) + A(w) • A( v) =  A(v) • In particular, A(0) = 0 • Linear operators we know: • Scaling • Rotation, reflection • Translation is not linear – moves the origin

Linear operators - illustration • Rotation is a linear operator: R(v+w) v+w w w v v

Linear operators - illustration • Rotation is a linear operator: R(v+w) v+w R(w) w w v v

Linear operators - illustration • Rotation is a linear operator: R(v+w) v+w R(v) R(w) w w v v

Linear operators - illustration • Rotation is a linear operator: R(v)+R(w) R(v+w) v+w R(v) R(w) w w v v R(v+w) = R(v) + R(w)

Matrix representation of linear operators • Look at A(v1),…, A(vn) where {v1, v2, …, vn} is a basis. • For all other vectors: v =1v1 + 2v2 + … + nvn A(v) =1A(v1) + 2A(v2) + … + nA(vn) • So, knowing what A does to the basis is enough • The matrix representing A is:

Matrix representation of linear operators

Matrix operations • Addition, subtraction, scalar multiplication – simple… • Multiplication of matrix by column vector: A b

Matrix by vector multiplication • Sometimes a better way to look at it: • Ab is a linear combination of A’s columns!

Matrix operations • Transposition: make the rows to be the columns • (AB)T = BTAT

Matrix operations • Inner product can in matrix form:

Matrix properties • Matrix A(nn) is non-singular if B, AB = BA = I • B = A1 is called the inverse of A • A is non-singular  det A  0 • If A is non-singular then the equation Ax=b has one unique solution for each b. • A is non-singular  the rows of A are linearly independent (and so are the columns).

Orthogonal matrices • Matrix A(nn)is orthogonal if A1 = AT • Follows: AAT = ATA = I • The rows of A are orthonormal vectors! Proof: v1 I = ATA = = viTvj = ij v1 v2 vn v2 vn  <vi,vi> = 1||vi|| = 1; <vi, vj> = 0

Orthogonal operators • A is orthogonal matrix A represents a linear operator that preserves inner product (i.e., preserves lengths and angles): • Therefore, ||Av|| = ||v|| and (Av,Aw) = (v,w)

Orthogonal operators - example • Rotation by  around the z-axis in R3 : • In fact, any orthogonal 33 matrix represents a rotation around some axis and/or a reflection • detA= +1rotation only • detA= 1with reflection

Eigenvectors and eigenvalues • Let A be a square nn matrix • v is eigenvector of A if: • Av = v ( is a scalar) • v 0 • The scalar  is called eigenvalue • Av = v A(v) = ( v)  vis also eigenvector • Av = v, Aw = w A(v+w) = (v+w) • Therefore, eigenvectors of the same  form a linear subspace.

Eigenvectors and eigenvalues • An eigenvector spans an axis (subspace of dimension 1) that is invariant to A – it remains the same under the transformation. • Example – the axis of rotation: Eigenvector of the rotation transformation O

Finding eigenvalues • For which  is there a non-zero solution to Ax = x? • Ax = x Ax – x = 0  Ax – Ix = 0  (AI)x = 0 • So, non trivial solution exists det(A – I) = 0 • A() = det(A – I) is a polynomial of degree n. • It is called the characteristic polynomial of A. • The roots of A are the eigenvalues of A. • Therefore, there are always at least complex eigenvalues. If n is odd, there is at least one real eigenvalue.

Example of computing A Cannot be factorized over R Over C:

Computing eigenvectors • Solve the equation (A – I)x = 0 • We’ll get a subspace of solutions.

Spectra and diagonalization • The set of all the eigenvalues of A is called the spectrum of A. • A is diagonalizable if A has n independent eigenvectors. Then: AV = VD A 1 2 = v1 v2 v1 v2 vn vn n

Spectra and diagonalization • Therefore, A = VDV1, where D is diagonal • A represents a scaling along the eigenvector axes! 1 A 1 2 = v1 v2 vn v1 v2 vn n A = VDV1

Spectra and diagonalization V D A rotation reflection other orthonormal basis orthonormal basis

Spectra and diagonalization A

Spectra and diagonalization A eigenbasis

Spectra and diagonalization • A is called normal if AAT = ATA. • Important example: symmetric matrices A = AT. • It can be proved that normal nn matrices have exactly n linearly independent eigenvectors (over C). • If A is symmetric, all eigenvalues of A are real, and it has n independent real orthonormal eigenvectors.

Why SVD… • Diagonalizable matrix is essentially a scaling. • Most matrices are not diagonalizable – they do other things along with scaling (such as rotation) • So, to understand how general matrices behave, only eigenvalues are not enough • SVD tells us how general linear transformations behave, and other things…

3D Geometry for Computer Graphics